mirror of
https://github.com/Sneed-Group/Poodletooth-iLand
synced 2024-12-25 04:32:33 -06:00
598 lines
32 KiB
Python
598 lines
32 KiB
Python
from pandac.PandaModules import *
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from pandac.PandaModules import ParticleSystem
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from pandac.PandaModules import BaseParticleFactory
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from pandac.PandaModules import PointParticleFactory
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from pandac.PandaModules import ZSpinParticleFactory
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#from pandac.PandaModules import OrientedParticleFactory
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from pandac.PandaModules import BaseParticleRenderer
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from pandac.PandaModules import PointParticleRenderer
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from pandac.PandaModules import LineParticleRenderer
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from pandac.PandaModules import GeomParticleRenderer
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from pandac.PandaModules import SparkleParticleRenderer
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#from pandac.PandaModules import SpriteParticleRenderer
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from pandac.PandaModules import BaseParticleEmitter
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from pandac.PandaModules import ArcEmitter
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from pandac.PandaModules import BoxEmitter
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from pandac.PandaModules import DiscEmitter
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from pandac.PandaModules import LineEmitter
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from pandac.PandaModules import PointEmitter
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from pandac.PandaModules import RectangleEmitter
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from pandac.PandaModules import RingEmitter
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from pandac.PandaModules import SphereSurfaceEmitter
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from pandac.PandaModules import SphereVolumeEmitter
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from pandac.PandaModules import TangentRingEmitter
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import SpriteParticleRendererExt
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import string
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import os
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from direct.directnotify.DirectNotifyGlobal import directNotify
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import sys
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class Particles(ParticleSystem):
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notify = directNotify.newCategory('Particles')
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id = 1
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def __init__(self, name=None, poolSize=1024):
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if (name == None):
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self.name = 'particles-%d' % Particles.id
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Particles.id += 1
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else:
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self.name = name
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ParticleSystem.__init__(self, poolSize)
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# self.setBirthRate(0.02)
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# self.setLitterSize(10)
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# self.setLitterSpread(0)
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# Set up a physical node
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self.node = PhysicalNode(self.name)
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self.nodePath = NodePath(self.node)
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self.setRenderParent(self.node)
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self.node.addPhysical(self)
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self.factory = None
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self.factoryType = "undefined"
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# self.setFactory("PointParticleFactory")
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self.renderer = None
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self.rendererType = "undefined"
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# self.setRenderer("PointParticleRenderer")
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self.emitter = None
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self.emitterType = "undefined"
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# self.setEmitter("SphereVolumeEmitter")
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# Enable particles by default
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self.fEnabled = 0
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#self.enable()
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self.geomReference = ""
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def cleanup(self):
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self.disable()
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self.clearLinearForces()
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self.clearAngularForces()
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self.setRenderParent(self.node)
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self.node.removePhysical(self)
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self.nodePath.removeNode()
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del self.node
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del self.nodePath
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del self.factory
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del self.renderer
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del self.emitter
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def enable(self):
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if (self.fEnabled == 0):
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base.physicsMgr.attachPhysical(self)
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base.particleMgr.attachParticlesystem(self)
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self.fEnabled = 1
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def disable(self):
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if (self.fEnabled == 1):
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base.physicsMgr.removePhysical(self)
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base.particleMgr.removeParticlesystem(self)
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self.fEnabled = 0
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def isEnabled(self):
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return self.fEnabled
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def getNode(self):
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return self.node
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def setFactory(self, type):
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if (self.factoryType == type):
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return None
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if (self.factory):
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self.factory = None
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self.factoryType = type
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if (type == "PointParticleFactory"):
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self.factory = PointParticleFactory()
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elif (type == "ZSpinParticleFactory"):
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self.factory = ZSpinParticleFactory()
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elif (type == "OrientedParticleFactory"):
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self.factory = OrientedParticleFactory()
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else:
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print "unknown factory type: %s" % type
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return None
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self.factory.setLifespanBase(0.5)
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ParticleSystem.setFactory(self, self.factory)
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def setRenderer(self, type):
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if (self.rendererType == type):
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return None
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if (self.renderer):
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self.renderer = None
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self.rendererType = type
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if (type == "PointParticleRenderer"):
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self.renderer = PointParticleRenderer()
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self.renderer.setPointSize(1.0)
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elif (type == "LineParticleRenderer"):
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self.renderer = LineParticleRenderer()
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elif (type == "GeomParticleRenderer"):
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self.renderer = GeomParticleRenderer()
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# This was moved here because we do not want to download
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# the direct tools with toontown.
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if __dev__:
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from direct.directtools import DirectSelection
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npath = NodePath('default-geom')
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bbox = DirectSelection.DirectBoundingBox(npath)
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self.renderer.setGeomNode(bbox.lines.node())
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elif (type == "SparkleParticleRenderer"):
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self.renderer = SparkleParticleRenderer()
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elif (type == "SpriteParticleRenderer"):
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self.renderer = SpriteParticleRendererExt.SpriteParticleRendererExt()
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# self.renderer.setTextureFromFile()
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else:
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print "unknown renderer type: %s" % type
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return None
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ParticleSystem.setRenderer(self, self.renderer)
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def setEmitter(self, type):
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if (self.emitterType == type):
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return None
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if (self.emitter):
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self.emitter = None
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self.emitterType = type
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if (type == "ArcEmitter"):
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self.emitter = ArcEmitter()
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elif (type == "BoxEmitter"):
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self.emitter = BoxEmitter()
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elif (type == "DiscEmitter"):
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self.emitter = DiscEmitter()
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elif (type == "LineEmitter"):
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self.emitter = LineEmitter()
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elif (type == "PointEmitter"):
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self.emitter = PointEmitter()
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elif (type == "RectangleEmitter"):
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self.emitter = RectangleEmitter()
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elif (type == "RingEmitter"):
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self.emitter = RingEmitter()
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elif (type == "SphereSurfaceEmitter"):
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self.emitter = SphereSurfaceEmitter()
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elif (type == "SphereVolumeEmitter"):
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self.emitter = SphereVolumeEmitter()
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self.emitter.setRadius(1.0)
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elif (type == "TangentRingEmitter"):
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self.emitter = TangentRingEmitter()
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else:
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print "unknown emitter type: %s" % type
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return None
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ParticleSystem.setEmitter(self, self.emitter)
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def addForce(self, force):
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if (force.isLinear()):
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self.addLinearForce(force)
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else:
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self.addAngularForce(force)
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def removeForce(self, force):
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if (force == None):
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self.notify.warning('removeForce() - force == None!')
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return
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if (force.isLinear()):
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self.removeLinearForce(force)
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else:
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self.removeAngularForce(force)
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def setRenderNodePath(self, nodePath):
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self.setRenderParent(nodePath.node())
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## Getters ##
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def getName(self):
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return self.name
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def getFactory(self):
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return self.factory
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def getEmitter(self):
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return self.emitter
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def getRenderer(self):
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return self.renderer
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def printParams(self, file = sys.stdout, targ = 'self'):
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file.write('# Particles parameters\n')
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file.write(targ + '.setFactory(\"' + self.factoryType + '\")\n')
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file.write(targ + '.setRenderer(\"' + self.rendererType + '\")\n')
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file.write(targ + '.setEmitter(\"' + self.emitterType + '\")\n')
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# System parameters
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file.write(targ + ('.setPoolSize(%d)\n' %
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int(self.getPoolSize())))
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file.write(targ + ('.setBirthRate(%.4f)\n' %
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self.getBirthRate()))
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file.write(targ + ('.setLitterSize(%d)\n' %
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int(self.getLitterSize())))
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file.write(targ + ('.setLitterSpread(%d)\n' %
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self.getLitterSpread()))
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file.write(targ + ('.setSystemLifespan(%.4f)\n' %
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self.getSystemLifespan()))
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file.write(targ + ('.setLocalVelocityFlag(%d)\n' %
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self.getLocalVelocityFlag()))
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file.write(targ + ('.setSystemGrowsOlderFlag(%d)\n' %
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self.getSystemGrowsOlderFlag()))
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file.write('# Factory parameters\n')
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file.write(targ + ('.factory.setLifespanBase(%.4f)\n' %
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self.factory.getLifespanBase()))
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file.write(targ + '.factory.setLifespanSpread(%.4f)\n' % \
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self.factory.getLifespanSpread())
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file.write(targ + '.factory.setMassBase(%.4f)\n' % \
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self.factory.getMassBase())
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file.write(targ + '.factory.setMassSpread(%.4f)\n' % \
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self.factory.getMassSpread())
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file.write(targ + '.factory.setTerminalVelocityBase(%.4f)\n' % \
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self.factory.getTerminalVelocityBase())
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file.write(targ + '.factory.setTerminalVelocitySpread(%.4f)\n' % \
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self.factory.getTerminalVelocitySpread())
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if (self.factoryType == "PointParticleFactory"):
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file.write('# Point factory parameters\n')
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elif (self.factoryType == "ZSpinParticleFactory"):
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file.write('# Z Spin factory parameters\n')
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file.write(targ + '.factory.setInitialAngle(%.4f)\n' % \
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self.factory.getInitialAngle())
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file.write(targ + '.factory.setInitialAngleSpread(%.4f)\n' % \
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self.factory.getInitialAngleSpread())
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file.write(targ + '.factory.enableAngularVelocity(%d)\n' % \
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self.factory.getAngularVelocityEnabled())
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if(self.factory.getAngularVelocityEnabled()):
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file.write(targ + '.factory.setAngularVelocity(%.4f)\n' % \
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self.factory.getAngularVelocity())
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file.write(targ + '.factory.setAngularVelocitySpread(%.4f)\n' % \
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self.factory.getAngularVelocitySpread())
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else:
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file.write(targ + '.factory.setFinalAngle(%.4f)\n' % \
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self.factory.getFinalAngle())
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file.write(targ + '.factory.setFinalAngleSpread(%.4f)\n' % \
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self.factory.getFinalAngleSpread())
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elif (self.factoryType == "OrientedParticleFactory"):
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file.write('# Oriented factory parameters\n')
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file.write(targ + '.factory.setInitialOrientation(%.4f)\n' % \
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self.factory.getInitialOrientation())
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file.write(targ + '.factory.setFinalOrientation(%.4f)\n' % \
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self.factory.getFinalOrientation())
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file.write('# Renderer parameters\n')
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alphaMode = self.renderer.getAlphaMode()
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aMode = "PRALPHANONE"
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if (alphaMode == BaseParticleRenderer.PRALPHANONE):
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aMode = "PRALPHANONE"
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elif (alphaMode == BaseParticleRenderer.PRALPHAOUT):
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aMode = "PRALPHAOUT"
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elif (alphaMode == BaseParticleRenderer.PRALPHAIN):
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aMode = "PRALPHAIN"
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elif (alphaMode == BaseParticleRenderer.PRALPHAINOUT):
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aMode = "PRALPHAINOUT"
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elif (alphaMode == BaseParticleRenderer.PRALPHAUSER):
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aMode = "PRALPHAUSER"
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file.write(targ + '.renderer.setAlphaMode(BaseParticleRenderer.' + aMode + ')\n')
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file.write(targ + '.renderer.setUserAlpha(%.2f)\n' % \
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self.renderer.getUserAlpha())
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if (self.rendererType == "PointParticleRenderer"):
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file.write('# Point parameters\n')
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file.write(targ + '.renderer.setPointSize(%.2f)\n' % \
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self.renderer.getPointSize())
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sColor = self.renderer.getStartColor()
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file.write((targ + '.renderer.setStartColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
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sColor = self.renderer.getEndColor()
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file.write((targ + '.renderer.setEndColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
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blendType = self.renderer.getBlendType()
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bType = "PPONECOLOR"
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if (blendType == PointParticleRenderer.PPONECOLOR):
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bType = "PPONECOLOR"
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elif (blendType == PointParticleRenderer.PPBLENDLIFE):
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bType = "PPBLENDLIFE"
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elif (blendType == PointParticleRenderer.PPBLENDVEL):
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bType = "PPBLENDVEL"
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file.write(targ + '.renderer.setBlendType(PointParticleRenderer.' + bType + ')\n')
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blendMethod = self.renderer.getBlendMethod()
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bMethod = "PPNOBLEND"
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if (blendMethod == BaseParticleRenderer.PPNOBLEND):
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bMethod = "PPNOBLEND"
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elif (blendMethod == BaseParticleRenderer.PPBLENDLINEAR):
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bMethod = "PPBLENDLINEAR"
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elif (blendMethod == BaseParticleRenderer.PPBLENDCUBIC):
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bMethod = "PPBLENDCUBIC"
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file.write(targ + '.renderer.setBlendMethod(BaseParticleRenderer.' + bMethod + ')\n')
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elif (self.rendererType == "LineParticleRenderer"):
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file.write('# Line parameters\n')
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sColor = self.renderer.getHeadColor()
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file.write((targ + '.renderer.setHeadColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
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sColor = self.renderer.getTailColor()
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file.write((targ + '.renderer.setTailColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
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sf = self.renderer.getLineScaleFactor()
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file.write((targ + '.renderer.setLineScaleFactor(%.2f)\n' % (sf)))
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elif (self.rendererType == "GeomParticleRenderer"):
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file.write('# Geom parameters\n')
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node = self.renderer.getGeomNode()
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file.write('geomRef = loader.loadModel("' + self.geomReference + '")\n')
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file.write(targ + '.renderer.setGeomNode(geomRef.node())\n')
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file.write(targ + '.geomReference = "' + self.geomReference + '"\n');
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cbmLut = ('MNone','MAdd','MSubtract','MInvSubtract','MMin','MMax')
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cboLut = ('OZero','OOne','OIncomingColor','OOneMinusIncomingColor','OFbufferColor',
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'OOneMinusFbufferColor','OIncomingAlpha','OOneMinusIncomingAlpha',
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'OFbufferAlpha','OOneMinusFbufferAlpha','OConstantColor',
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'OOneMinusConstantColor','OConstantAlpha','OOneMinusConstantAlpha',
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'OIncomingColorSaturate')
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file.write(targ + '.renderer.setXScaleFlag(%d)\n' % self.renderer.getXScaleFlag())
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file.write(targ + '.renderer.setYScaleFlag(%d)\n' % self.renderer.getYScaleFlag())
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file.write(targ + '.renderer.setZScaleFlag(%d)\n' % self.renderer.getZScaleFlag())
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file.write(targ + '.renderer.setInitialXScale(%.4f)\n' % self.renderer.getInitialXScale())
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file.write(targ + '.renderer.setFinalXScale(%.4f)\n' % self.renderer.getFinalXScale())
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file.write(targ + '.renderer.setInitialYScale(%.4f)\n' % self.renderer.getInitialYScale())
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file.write(targ + '.renderer.setFinalYScale(%.4f)\n' % self.renderer.getFinalYScale())
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file.write(targ + '.renderer.setInitialZScale(%.4f)\n' % self.renderer.getInitialZScale())
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file.write(targ + '.renderer.setFinalZScale(%.4f)\n' % self.renderer.getFinalZScale())
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cbAttrib = self.renderer.getRenderNode().getAttrib(ColorBlendAttrib.getClassType())
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if(cbAttrib):
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cbMode = cbAttrib.getMode()
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if(cbMode > 0):
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if(cbMode in (ColorBlendAttrib.MAdd, ColorBlendAttrib.MSubtract, ColorBlendAttrib.MInvSubtract)):
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cboa = cbAttrib.getOperandA()
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cbob = cbAttrib.getOperandB()
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file.write(targ+'.renderer.setColorBlendMode(ColorBlendAttrib.%s, ColorBlendAttrib.%s, ColorBlendAttrib.%s)\n' %
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(cbmLut[cbMode], cboLut[cboa], cboLut[cbob]))
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else:
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file.write(targ+'.renderer.setColorBlendMode(ColorBlendAttrib.%s)\n' % cbmLut[cbMode])
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cim = self.renderer.getColorInterpolationManager()
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segIdList = [int(seg) for seg in cim.getSegmentIdList().split()]
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for sid in segIdList:
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seg = cim.getSegment(sid)
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if seg.isEnabled():
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t_b = seg.getTimeBegin()
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t_e = seg.getTimeEnd()
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mod = seg.isModulated()
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fun = seg.getFunction()
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typ = type(fun).__name__
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if typ == 'ColorInterpolationFunctionConstant':
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c_a = fun.getColorA()
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file.write(targ+'.renderer.getColorInterpolationManager().addConstant('+repr(t_b)+','+repr(t_e)+','+ \
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'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),'+repr(mod)+')\n')
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elif typ == 'ColorInterpolationFunctionLinear':
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c_a = fun.getColorA()
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c_b = fun.getColorB()
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file.write(targ+'.renderer.getColorInterpolationManager().addLinear('+repr(t_b)+','+repr(t_e)+','+ \
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'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),' + \
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'Vec4('+repr(c_b[0])+','+repr(c_b[1])+','+repr(c_b[2])+','+repr(c_b[3])+'),'+repr(mod)+')\n')
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elif typ == 'ColorInterpolationFunctionStepwave':
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c_a = fun.getColorA()
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c_b = fun.getColorB()
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w_a = fun.getWidthA()
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w_b = fun.getWidthB()
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file.write(targ+'.renderer.getColorInterpolationManager().addStepwave('+repr(t_b)+','+repr(t_e)+','+ \
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'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),' + \
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'Vec4('+repr(c_b[0])+','+repr(c_b[1])+','+repr(c_b[2])+','+repr(c_b[3])+'),' + \
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repr(w_a)+','+repr(w_b)+','+repr(mod)+')\n')
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elif typ == 'ColorInterpolationFunctionSinusoid':
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c_a = fun.getColorA()
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c_b = fun.getColorB()
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per = fun.getPeriod()
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file.write(targ+'.renderer.getColorInterpolationManager().addSinusoid('+repr(t_b)+','+repr(t_e)+','+ \
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'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),' + \
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'Vec4('+repr(c_b[0])+','+repr(c_b[1])+','+repr(c_b[2])+','+repr(c_b[3])+'),' + \
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repr(per)+','+repr(mod)+')\n')
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elif (self.rendererType == "SparkleParticleRenderer"):
|
|
file.write('# Sparkle parameters\n')
|
|
sColor = self.renderer.getCenterColor()
|
|
file.write((targ + '.renderer.setCenterColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
|
|
sColor = self.renderer.getEdgeColor()
|
|
file.write((targ + '.renderer.setEdgeColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
|
|
file.write(targ + '.renderer.setBirthRadius(%.4f)\n' % self.renderer.getBirthRadius())
|
|
file.write(targ + '.renderer.setDeathRadius(%.4f)\n' % self.renderer.getDeathRadius())
|
|
lifeScale = self.renderer.getLifeScale()
|
|
lScale = "SPNOSCALE"
|
|
if (lifeScale == SparkleParticleRenderer.SPSCALE):
|
|
lScale = "SPSCALE"
|
|
file.write(targ + '.renderer.setLifeScale(SparkleParticleRenderer.' + lScale + ')\n')
|
|
elif (self.rendererType == "SpriteParticleRenderer"):
|
|
file.write('# Sprite parameters\n')
|
|
if (self.renderer.getAnimateFramesEnable()):
|
|
file.write(targ + '.renderer.setAnimateFramesEnable(True)\n')
|
|
rate = self.renderer.getAnimateFramesRate()
|
|
if(rate):
|
|
file.write(targ + '.renderer.setAnimateFramesRate(%.3f)\n'%rate)
|
|
animCount = self.renderer.getNumAnims()
|
|
for x in range(animCount):
|
|
anim = self.renderer.getAnim(x)
|
|
if(anim.getSourceType() == SpriteAnim.STTexture):
|
|
file.write(targ + '.renderer.addTextureFromFile(\'%s\')\n' % (anim.getTexSource(),))
|
|
else:
|
|
file.write(targ + '.renderer.addTextureFromNode(\'%s\',\'%s\')\n' % (anim.getModelSource(), anim.getNodeSource()))
|
|
sColor = self.renderer.getColor()
|
|
file.write((targ + '.renderer.setColor(Vec4(%.2f, %.2f, %.2f, %.2f))\n' % (sColor[0], sColor[1], sColor[2], sColor[3])))
|
|
file.write(targ + '.renderer.setXScaleFlag(%d)\n' % self.renderer.getXScaleFlag())
|
|
file.write(targ + '.renderer.setYScaleFlag(%d)\n' % self.renderer.getYScaleFlag())
|
|
file.write(targ + '.renderer.setAnimAngleFlag(%d)\n' % self.renderer.getAnimAngleFlag())
|
|
file.write(targ + '.renderer.setInitialXScale(%.4f)\n' % self.renderer.getInitialXScale())
|
|
file.write(targ + '.renderer.setFinalXScale(%.4f)\n' % self.renderer.getFinalXScale())
|
|
file.write(targ + '.renderer.setInitialYScale(%.4f)\n' % self.renderer.getInitialYScale())
|
|
file.write(targ + '.renderer.setFinalYScale(%.4f)\n' % self.renderer.getFinalYScale())
|
|
file.write(targ + '.renderer.setNonanimatedTheta(%.4f)\n' % self.renderer.getNonanimatedTheta())
|
|
blendMethod = self.renderer.getAlphaBlendMethod()
|
|
bMethod = "PPNOBLEND"
|
|
if (blendMethod == BaseParticleRenderer.PPNOBLEND):
|
|
bMethod = "PPNOBLEND"
|
|
elif (blendMethod == BaseParticleRenderer.PPBLENDLINEAR):
|
|
bMethod = "PPBLENDLINEAR"
|
|
elif (blendMethod == BaseParticleRenderer.PPBLENDCUBIC):
|
|
bMethod = "PPBLENDCUBIC"
|
|
file.write(targ + '.renderer.setAlphaBlendMethod(BaseParticleRenderer.' + bMethod + ')\n')
|
|
file.write(targ + '.renderer.setAlphaDisable(%d)\n' % self.renderer.getAlphaDisable())
|
|
# Save the color blending to file
|
|
cbmLut = ('MNone','MAdd','MSubtract','MInvSubtract','MMin','MMax')
|
|
cboLut = ('OZero','OOne','OIncomingColor','OOneMinusIncomingColor','OFbufferColor',
|
|
'OOneMinusFbufferColor','OIncomingAlpha','OOneMinusIncomingAlpha',
|
|
'OFbufferAlpha','OOneMinusFbufferAlpha','OConstantColor',
|
|
'OOneMinusConstantColor','OConstantAlpha','OOneMinusConstantAlpha',
|
|
'OIncomingColorSaturate')
|
|
cbAttrib = self.renderer.getRenderNode().getAttrib(ColorBlendAttrib.getClassType())
|
|
if(cbAttrib):
|
|
cbMode = cbAttrib.getMode()
|
|
if(cbMode > 0):
|
|
if(cbMode in (ColorBlendAttrib.MAdd, ColorBlendAttrib.MSubtract, ColorBlendAttrib.MInvSubtract)):
|
|
cboa = cbAttrib.getOperandA()
|
|
cbob = cbAttrib.getOperandB()
|
|
file.write(targ+'.renderer.setColorBlendMode(ColorBlendAttrib.%s, ColorBlendAttrib.%s, ColorBlendAttrib.%s)\n' %
|
|
(cbmLut[cbMode], cboLut[cboa], cboLut[cbob]))
|
|
else:
|
|
file.write(targ+'.renderer.setColorBlendMode(ColorBlendAttrib.%s)\n' % cbmLut[cbMode])
|
|
cim = self.renderer.getColorInterpolationManager()
|
|
segIdList = [int(seg) for seg in cim.getSegmentIdList().split()]
|
|
for sid in segIdList:
|
|
seg = cim.getSegment(sid)
|
|
if seg.isEnabled():
|
|
t_b = seg.getTimeBegin()
|
|
t_e = seg.getTimeEnd()
|
|
mod = seg.isModulated()
|
|
fun = seg.getFunction()
|
|
typ = type(fun).__name__
|
|
if typ == 'ColorInterpolationFunctionConstant':
|
|
c_a = fun.getColorA()
|
|
file.write(targ+'.renderer.getColorInterpolationManager().addConstant('+repr(t_b)+','+repr(t_e)+','+ \
|
|
'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),'+repr(mod)+')\n')
|
|
elif typ == 'ColorInterpolationFunctionLinear':
|
|
c_a = fun.getColorA()
|
|
c_b = fun.getColorB()
|
|
file.write(targ+'.renderer.getColorInterpolationManager().addLinear('+repr(t_b)+','+repr(t_e)+','+ \
|
|
'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),' + \
|
|
'Vec4('+repr(c_b[0])+','+repr(c_b[1])+','+repr(c_b[2])+','+repr(c_b[3])+'),'+repr(mod)+')\n')
|
|
elif typ == 'ColorInterpolationFunctionStepwave':
|
|
c_a = fun.getColorA()
|
|
c_b = fun.getColorB()
|
|
w_a = fun.getWidthA()
|
|
w_b = fun.getWidthB()
|
|
file.write(targ+'.renderer.getColorInterpolationManager().addStepwave('+repr(t_b)+','+repr(t_e)+','+ \
|
|
'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),' + \
|
|
'Vec4('+repr(c_b[0])+','+repr(c_b[1])+','+repr(c_b[2])+','+repr(c_b[3])+'),' + \
|
|
repr(w_a)+','+repr(w_b)+','+repr(mod)+')\n')
|
|
elif typ == 'ColorInterpolationFunctionSinusoid':
|
|
c_a = fun.getColorA()
|
|
c_b = fun.getColorB()
|
|
per = fun.getPeriod()
|
|
file.write(targ+'.renderer.getColorInterpolationManager().addSinusoid('+repr(t_b)+','+repr(t_e)+','+ \
|
|
'Vec4('+repr(c_a[0])+','+repr(c_a[1])+','+repr(c_a[2])+','+repr(c_a[3])+'),' + \
|
|
'Vec4('+repr(c_b[0])+','+repr(c_b[1])+','+repr(c_b[2])+','+repr(c_b[3])+'),' + \
|
|
repr(per)+','+repr(mod)+')\n')
|
|
|
|
file.write('# Emitter parameters\n')
|
|
emissionType = self.emitter.getEmissionType()
|
|
eType = "ETEXPLICIT"
|
|
if (emissionType == BaseParticleEmitter.ETEXPLICIT):
|
|
eType = "ETEXPLICIT"
|
|
elif (emissionType == BaseParticleEmitter.ETRADIATE):
|
|
eType = "ETRADIATE"
|
|
elif (emissionType == BaseParticleEmitter.ETCUSTOM):
|
|
eType = "ETCUSTOM"
|
|
file.write(targ + '.emitter.setEmissionType(BaseParticleEmitter.' + eType + ')\n')
|
|
file.write(targ + '.emitter.setAmplitude(%.4f)\n' % self.emitter.getAmplitude())
|
|
file.write(targ + '.emitter.setAmplitudeSpread(%.4f)\n' % self.emitter.getAmplitudeSpread())
|
|
oForce = self.emitter.getOffsetForce()
|
|
file.write((targ + '.emitter.setOffsetForce(Vec3(%.4f, %.4f, %.4f))\n' % (oForce[0], oForce[1], oForce[2])))
|
|
oForce = self.emitter.getExplicitLaunchVector()
|
|
file.write((targ + '.emitter.setExplicitLaunchVector(Vec3(%.4f, %.4f, %.4f))\n' % (oForce[0], oForce[1], oForce[2])))
|
|
orig = self.emitter.getRadiateOrigin()
|
|
file.write((targ + '.emitter.setRadiateOrigin(Point3(%.4f, %.4f, %.4f))\n' % (orig[0], orig[1], orig[2])))
|
|
if (self.emitterType == "BoxEmitter"):
|
|
file.write('# Box parameters\n')
|
|
bound = self.emitter.getMinBound()
|
|
file.write((targ + '.emitter.setMinBound(Point3(%.4f, %.4f, %.4f))\n' % (bound[0], bound[1], bound[2])))
|
|
bound = self.emitter.getMaxBound()
|
|
file.write((targ + '.emitter.setMaxBound(Point3(%.4f, %.4f, %.4f))\n' % (bound[0], bound[1], bound[2])))
|
|
elif (self.emitterType == "DiscEmitter"):
|
|
file.write('# Disc parameters\n')
|
|
file.write(targ + '.emitter.setRadius(%.4f)\n' % self.emitter.getRadius())
|
|
if (eType == "ETCUSTOM"):
|
|
file.write(targ + '.emitter.setOuterAngle(%.4f)\n' % self.emitter.getOuterAngle())
|
|
file.write(targ + '.emitter.setInnerAngle(%.4f)\n' % self.emitter.getInnerAngle())
|
|
file.write(targ + '.emitter.setOuterMagnitude(%.4f)\n' % self.emitter.getOuterMagnitude())
|
|
file.write(targ + '.emitter.setInnerMagnitude(%.4f)\n' % self.emitter.getInnerMagnitude())
|
|
file.write(targ + '.emitter.setCubicLerping(%d)\n' % self.emitter.getCubicLerping())
|
|
|
|
elif (self.emitterType == "LineEmitter"):
|
|
file.write('# Line parameters\n')
|
|
point = self.emitter.getEndpoint1()
|
|
file.write((targ + '.emitter.setEndpoint1(Point3(%.4f, %.4f, %.4f))\n' % (point[0], point[1], point[2])))
|
|
point = self.emitter.getEndpoint2()
|
|
file.write((targ + '.emitter.setEndpoint2(Point3(%.4f, %.4f, %.4f))\n' % (point[0], point[1], point[2])))
|
|
elif (self.emitterType == "PointEmitter"):
|
|
file.write('# Point parameters\n')
|
|
point = self.emitter.getLocation()
|
|
file.write((targ + '.emitter.setLocation(Point3(%.4f, %.4f, %.4f))\n' % (point[0], point[1], point[2])))
|
|
elif (self.emitterType == "RectangleEmitter"):
|
|
file.write('# Rectangle parameters\n')
|
|
point = self.emitter.getMinBound()
|
|
file.write((targ + '.emitter.setMinBound(Point2(%.4f, %.4f))\n' % (point[0], point[1])))
|
|
point = self.emitter.getMaxBound()
|
|
file.write((targ + '.emitter.setMaxBound(Point2(%.4f, %.4f))\n' % (point[0], point[1])))
|
|
elif (self.emitterType == "RingEmitter"):
|
|
file.write('# Ring parameters\n')
|
|
file.write(targ + '.emitter.setRadius(%.4f)\n' % self.emitter.getRadius())
|
|
file.write(targ + '.emitter.setRadiusSpread(%.4f)\n' % self.emitter.getRadiusSpread())
|
|
if (eType == "ETCUSTOM"):
|
|
file.write(targ + '.emitter.setAngle(%.4f)\n' % self.emitter.getAngle())
|
|
elif (self.emitterType == "SphereSurfaceEmitter"):
|
|
file.write('# Sphere Surface parameters\n')
|
|
file.write(targ + '.emitter.setRadius(%.4f)\n' % self.emitter.getRadius())
|
|
elif (self.emitterType == "SphereVolumeEmitter"):
|
|
file.write('# Sphere Volume parameters\n')
|
|
file.write(targ + '.emitter.setRadius(%.4f)\n' % self.emitter.getRadius())
|
|
elif (self.emitterType == "TangentRingEmitter"):
|
|
file.write('# Tangent Ring parameters\n')
|
|
file.write(targ + '.emitter.setRadius(%.4f)\n' % self.emitter.getRadius())
|
|
file.write(targ + '.emitter.setRadiusSpread(%.4f)\n' % self.emitter.getRadiusSpread())
|
|
|
|
def getPoolSizeRanges(self):
|
|
litterRange = [max(1,self.getLitterSize()-self.getLitterSpread()),
|
|
self.getLitterSize(),
|
|
self.getLitterSize()+self.getLitterSpread()]
|
|
lifespanRange = [self.factory.getLifespanBase()-self.factory.getLifespanSpread(),
|
|
self.factory.getLifespanBase(),
|
|
self.factory.getLifespanBase()+self.factory.getLifespanSpread()]
|
|
birthRateRange = [self.getBirthRate()] * 3
|
|
|
|
print 'Litter Ranges: ',litterRange
|
|
print 'LifeSpan Ranges: ',lifespanRange
|
|
print 'BirthRate Ranges: ',birthRateRange
|
|
|
|
return dict(zip(('min','median','max'),[l*s/b for l,s,b in zip(litterRange,lifespanRange,birthRateRange)]))
|
|
|
|
|
|
def accelerate(self,time,stepCount = 1,stepTime=0.0):
|
|
if time > 0.0:
|
|
if stepTime == 0.0:
|
|
stepTime = float(time)/stepCount
|
|
remainder = 0.0
|
|
else:
|
|
stepCount = int(float(time)/stepTime)
|
|
remainder = time-stepCount*stepTime
|
|
|
|
for step in range(stepCount):
|
|
base.particleMgr.doParticles(stepTime,self,False)
|
|
base.physicsMgr.doPhysics(stepTime,self)
|
|
|
|
if(remainder):
|
|
base.particleMgr.doParticles(remainder,self,False)
|
|
base.physicsMgr.doPhysics(remainder,self)
|
|
|
|
self.render()
|
|
|